NMR Evidence for Complexing of Na+ in Muscle, Kidney, and Brain, and by Actomyosin. The Relation of Cellular Complexing of Na+ to Water Structure and to Transport Kinetics

The nuclear magnetic resonance (NMR) spectrum of Na⁺ is suitable for qualitative and quantitative analysis of Na⁺ in tissues. The width of the NMR spectrum is dependent upon the environment surrounding the individual Na⁺ ion. NMR spectra of fresh muscle compared with spectra of the same samples after ashing show that approximately 70% of total muscle Na⁺ gives no detectable NMR spectrum. This is probably due to complexation of Na⁺ with macromolecules, which causes the NMR spectrum to be broadened beyond detection. A similar effect has been observed when Na⁺ interacts with ion exchange resin. NMR also indicates that about 60% of Na⁺ of kidney and brain is complexed. Destruction of cell structure of muscle by homogenization little alters the per cent complexing of Na⁺. NMR studies show that Na⁺ is complexed by actomyosin, which may be the molecular site of complexation of some Na⁺ in muscle. The same studies indicate that the solubility of Na⁺ in the interstitial water of actomyosin gel is markedly reduced compared with its solubility in liquid water, which suggests that the water in the gel is organized into an icelike state by the nearby actomyosin molecules. If a major fraction of intracellular Na⁺ exists in a complexed state, then major revisions in most theoretical treatments of equilibria, diffusion, and transport of cellular Na⁺ become appropriate.     

Nuclear Magnetic Resonance Studies of Sodium Ions in Isolated Frog Muscle and Liver

Nuclear magnetic resonance (NMR) was used to determine Na⁺ complexing in muscle and liver (at 23°C) from bullfrogs (Rana catesbeiana) and to study the influence of temperature on Na⁺ complexing in muscle from leopard frogs (Rana pipiens). The Na⁺ complexed in muscle and liver was found to be 36.6 ± 4.6% and 66.1 ± 3.5% respectively. A temperature decrease from +34°C to -2°C results in a 20% decrease in the mobility of the free Na⁺ in the fresh muscle. This 20% decrease in mobility results in about 50% of the free Na⁺ at 34°C being complexed at the lower temperature.     

ANALYSIS OF SODIUM TRANSPORT IN THE AMPHIBIAN OOCYTE BY EXTRACTIVE AND RADIOAUTOGRAPHIC TECHNIQUES

The transport of Na⁺ in mature Eurycea oocytes was studied by quantitative radioautography of ²²Na⁺ using techniques suitable for localization of diffusible solutes, together with conventional extractive techniques. Intracellular Na⁺ consisted of three kinetic fractions: a cytoplasmic fast fraction of about 8.5 µeq/ml H₂O; a cytoplasmic slow fraction of about 58.7 µeq/ml H₂O; and a nuclear fast fraction of about 11.1 µeq/ml H₂O. A nuclear slow fraction, if it exists, does not exceed 5% of the cytoplasmic. The fast fractions represent freely diffusible Na⁺ in the two compartments; the nuclear solvent space is 1.3 times the cytoplasmic. The flux of both fast fractions is determined by the permeability of the cortical membrane, with neither the nuclear membrane nor diffusion in the cytoplasm detectably slowing the flux. The cytoplasmic slow fraction is interpreted to represent Na⁺ bound to nondiffusible constituents which are excluded from the nucleus; these may be yolk platelets, although the widespread observation of Na⁺ binding in other cells, and the high Na⁺/K⁺ selectivity, argues against simple ion-binding to the yolk phosphoprotein.     

Nuclear Magnetic Resonance Evidence using D2O for Structured Water in Muscle and Brain

The electric quadrupole moment of the deuterium nucleus provides a nuclear magnetic resonance (NMR) probe of electric field gradients, and thereby of organization of tissue water. 8-17% of H₂O in rat muscle and brain was replaced by D₂O from 50% deuterated drinking water. The peak height of the steady-state NMR spectrum of D in muscle water was 74% lower than that of an equal concentration of D₂O in liquid water. Longitudinal NMR relaxation times (T₁) of D in water of muscle and brain averaged 0.092 and 0.131 sec, respectively, compared with 0.47 sec in D₂O in liquid water. Transverse NMR relaxation times (T₂) averaged 0.009 and 0.022 sec in D₂O of muscle and brain, respectively, compared with 0.45 sec in D₂O in liquid water. These differences cannot be explained by paramagnetic ions or by magnetic inhomogeneities, which leaves increased organization of tissue water as the only tenable hypothesis. Evidence was also obtained that 27% of muscle water and 13% of brain water exist as a separate fraction with T₂ of D₂O less than 2 × 10^-3 sec, which implies an even higher degree of structure. Each of the two fractions may consist of multiple subfractions of differing structure.     

A non-equilibrium thermodynamic theory of leakage of complexed Na+ from muscle,with NMR evidence that the non-complexed fraction of muscle Na+ is intra-vacuolar rather than extra-cellular

Recent experimental evidence has provided increasing support for the hypotheses that 60 to 80 per cent of intracellular Na⁺ exists in a complexed state, and that intracellular water exists in a semi-organized, non-liquid state having low solubility for Na⁺. Using these postulates, a previous crude theory of Na⁺ leakage from the cell based on electronion conduction analogies has been redeveloped in a more complete and detailed fashion, following a non-equilibrium thermodynamic approach. The theory, which is based on the postulate of almost 100 per cent complexing of intracellular Na⁺, predicts that Na⁺ leakage from muscle should conform to the Elovich equation, which closely agrees with experiment, despite the fact that experiments indicate that 20 to 40 per cent of muscle Na⁺ isnot complexed. To resolve this apparent paradox, the leakage of complexed and non-complexed Na⁺ from muscle was measured by nuclear magnetic resonance (NMR). The non-complexed Na⁺ leaked much more slowly than the complexed Na⁺, suggesting that the non-complexed Na⁺ may be confined within vacuoles surrounded by an activation energy barrier at the vacuolar membrane. This implies that the measured curves of Na⁺ leakage showing Elovich kinetics are due mostly to leakage of complexed Na⁺ as the theory requires, and that the leakage of 20 to 40 per cent non-complexed Na⁺ is mostly delayed until later times.     

23Na Magnetic Resonance Imaging of the Lower Leg of Acute Heart Failure Patients during Diuretic Treatment

Objective

Na⁺ can be stored in muscle and skin without commensurate water accumulation. The aim of this study was to assess Na⁺ and H₂O in muscle and skin with MRI in acute heart failure patients before and after diuretic treatment and in a healthy cohort.

Methods

Nine patients (mean age 78 years; range 58–87) and nine age and gender-matched controls were studied. They underwent ²³Na/¹H-MRI at the calf with a custom-made knee coil. Patients were studied before and after diuretic therapy. ²³Na-MRI gray-scale measurements of Na⁺-phantoms served to quantify Na⁺-concentrations. A fat-suppressed inversion recovery sequence was used to quantify H₂O content.

Results

Plasma Na⁺-levels did not change during therapy. Mean Na⁺-concentrations in muscle and skin decreased after furosemide therapy (before therapy: 30.7±6.4 and 43.5±14.5 mmol/L; after therapy: 24.2±6.1 and 32.2±12.0 mmol/L; p˂0.05 and p˂0.01). Water content measurements did not differ significantly before and after furosemide therapy in muscle (p = 0.17) and only tended to be reduced in skin (p = 0.06). Na⁺-concentrations in calf muscle and skin of patients before and after diuretic therapy were significantly higher than in healthy subjects (18.3±2.5 and 21.1±2.3 mmol/L).

Conclusions

²³Na-MRI shows accumulation of Na⁺ in muscle and skin in patients with acute heart failure. Diuretic treatment can mobilize this Na⁺-deposition; however, contrary to expectations, water and Na⁺-mobilization are poorly correlated.     

Lack of stimulation of renal (Na+ + K+)-ATPase by thyroid hormones in the rabbit

The effect of l-3,5,3′-triiodothyronine (T₃) and thyroxine (T₄) on (Na⁺ + K⁺)-ATPase activities was examined in rabbit kidneys because in this tissue almost 80% of the metabolism is connected to active sodium transport. T₃-receptor concentrations were estimated as 0.62 and 0.80 pmol/mg per DNA in the cortex and outer medulla, respectively. A dose of 0.5 mg T₃/kg body weight for 3 days increased basal metabolic rate by almost 60%, and the mitochondrial 1-α-glycerophosphate dehydrogenase activity was increased by 50% in both the cortex and medulla. (Na⁺ + K⁺)-ATPase activity in the liver was raised by almost 50%. However, no changes in (Na⁺ + K⁺)-ATPase activities or binding sites for [³H]ouabain in either the kidney cortex or medulla could be observed. T₄ at 16 mg/kg daily for 14 days was also without effect on renal (Na⁺ + K⁺)-ATPase activities. Furthermore, the response to T₃ was absent at high sodium excretion rates induced by unilateral nephrectomy and extracellular volume expansion. Thus, despite stimulation of basal metabolic rate and renal 1-α-glycerophosphate dehydrogenase activity by T₃ and T₄, the (Na⁺ + K⁺)-ATPase activity in the rabbit kidney is identical in euthyroid and hyperthyroid states. However, thyroid hormones prevent the normal natriuretic response to extracellular volume expansion.     

Isolated epithelial cells of the toad bladder. Their preparation, oxygen consumption, and electrolyte content

Epithelial cells of the toad bladder were disaggregated with EDTA, trypsin, hyaluronidase, or collagenase and were then scraped free of the underlying connective tissue. In most experiments EDTA was complexed with a divalent cation before the tissue was scraped. Q _OO2, sucrose and inulin spaces, and electrolytes of the isolated cells were measured. Cells disaggregated by collagenase or hyaluronidase consumed O₂ at a rate of 4 µl hr^-1 dry wt^-1. Q _OO2 was increased 50% by ADH (100 U/liter) or by cyclic 3'',5''-AMP (10 mM/liter). Na⁺-free Ringer''s depressed the Q _OO2 by 40%. The Q _OO2 of cells prepared by trypsin treatment or by two EDTA methods was depressed by Na⁺-free Ringer''s but was stimulated relatively little by ADH. Two other EDTA protocols produced cells that did not respond to Na⁺ lack or ADH. The intracellular Na⁺ and K⁺ concentrations of collagenase-disaggregated cells were 32 and 117 mEq/kg cell H₂O, respectively. Cation concentrations of hyaluronidase cells were similar, but cells that did not respond to ADH had higher intracellular Na⁺ concentrations. Cells unresponsive to ADH and Na⁺ lack had high sucrose spaces and low transcellular membrane gradients of Na⁺, K⁺, and Cl^-. The results suggest that trypsin and EDTA disaggregation damage the active Na⁺ transport system of the isolated cell. Certain EDTA techniques may also produce a general increase in permeability. Collagenase and hyaluronidase cells appear to function normally.     

Water in normal muscle and muscle with a tumor

The total water content, the amount of non-freezable water, and the Na⁺ and K⁺ contents in the gastrocnemius muscle of albino mice with and without a solid tumor were determined. The spin-lattice relaxation time (T₁) for the water protons in the two kinds of muscle were measured at six resonance frequencies ranging from 4.5 to 60 MHz over the temperature range +37 to −65°C. Quantitatively calculated T₁ values are given. The difference in T₁ for the two types of muscle at temperatures above −5°C is attributed to the difference in the distribution ratio of water between hydration and free states, and bears no direct relation to the concentration of Na⁺.     

Effect of tissue specificity of brain soluble fractions on Na+, K+-ATPase activity

Previous evidence from this laboratory indicated that catecholamines and brain endogenous factors modulate Na⁺, K⁺-ATPase activity of the synaptosomal membranes. The filtration of a brain total soluble fraction through Sephadex G-50 permitted the separation of two fractions-peaks I and II-which stimulated and inhibited Na⁺, K⁺-ATPase, respectively (Rodríguez de Lores Arnaiz and Antonelli de Gomez de Lima, Neurochem. Res.11, 1986, 933). In order to study tissue specificity a rat kidney total soluble was fractionated in Sephadex G-50 and kidney peak I and II fractions were separated; as control, a total soluble fraction prepared from rat cerebral cortex was also processed. The UV absorbance profile of the kidney total soluble showed two zones and was similar to the profile of the brain total soluble. Synaptosomal membranes Na⁺, K⁺- and Mg²⁺-ATPases were stimulated 60–100% in the presence of kidney and cerebral cortex peak I; Na⁺, K⁺-ATPase was inhibited 35–65% by kidney peak II and 60–80% by brain peak II. Mg²⁺-ATPase activity was not modified by peak II fractions. ATPases activity of a kidney crude microsomal fraction was not modified by kidney peak I or brain peak II, and was slightly increased by kidney peak II or brain peak I. Kidney purified Na⁺, K⁺-ATPase was increased 16–20% by brain peak I and II fractions. These findings indicate that modulatory factors of ATPase activity are not exclusive to the brain. On the contrary, there might be tissue specificity with respect to the enzyme source.     

Tissue specificity of dopamine effects on brain ATPases

Dopamine inhibits Mg²⁺,Na⁺,K⁺- and Na⁺,K⁺-ATPase activities but does not modify Mg²⁺-ATPase activity of nerve ending membranes isolated from rat cerebral cortex. In the presence of the soluble fraction of brain, dopamine activates total, Na⁺,K⁺-, and Mg²⁺-ATPases. Dopamine stimulation of nerve ending membrane ATPases is achieved when soluble fractions of brain, kidney, or liver are used. On the other hand, dopamine effects are not observed on kidney or heart ATPase preparations. These results indicate tissue specificity of dopamine effects with respect to the enzyme source; there is no tissue specificity for the requirement of the soluble fraction to achieve stimulation of ATPases by dopamine.     

The Sodium-Potassium Exchange Pump: II. Analysis of Na+-Loaded Frog Sartorius Muscle

A model for the Na-K exchange pump was applied to data on Na⁺-loaded frog sartorius muscle, and was used to relate the rate of adenosine triphosphate (ATP) hydrolysis to the electrical properties of the cell membrane. Membrane hyperpolarization was considered to arise from an electrical current which was produced by the hydrolysis reaction coupled to ion movements, and which flowed across the membrane. The reaction rate, as calculated from hyperpolarization, agreed with direct measurements of ATP hydrolysis and with the rate estimated from Na⁺ tracer efflux studies. Although Na⁺ is actively extruded, the model showed that K⁺ is inwardly transported if the potassium permeability of the membrane is less than about 6.6 × 10^-6 cm/sec, as is suggested by resistance data. Calculations indicated that the reaction conductance L_rr was relatively constant when compared with the reaction rate and reaction free energy for large changes in internal and external ionic concentrations. Its value agreed with the value obtained from the dependence of Na⁺ tracer efflux on external K⁺. A set of experiments was suggested which would provide a more complete interpretation of the data.     

The subunit fine structure of isolated, purified Na,K-adenosine triphosphatase : Freeze-fracture study

The ultrastructural features of a purified fraction of Na⁺,K⁺-adenosine triphosphatase (ATPase) isolated from dog kidney medulla were compared with those of the initial crude microsomal fraction in the purification sequence. Although both fractions consist of vesicular structures, the purified fraction is more homogeneous with respect to overall size and intramembrane protein particle size and distribution. Polyacrylamide gel electrophoresis profiles of both fractions reveal multiple proteins in the microsomal fraction but only two in the final purified fraction. The membranes of the pure fraction comprised one class of particles roughly 95–120 Å in diameter which represent the in vitro configuration of Na⁺,K⁺-ATPase.     

Asymmetric incorporation of Na+, K+-ATPase into phospholipid vesicles

Purified lamb kidney Na⁺, K⁺-ATPase, consisting solely of the Mτ = 95,000 catalytic subunit and the M_τ～- 44,000 glycoprotein, was solubilized with Triton X-100 and incorporated into unilamellar phospholipid vesicles. Freeze-fracture electron microscopy of the vesicles showed intramembranous particles of approximately 90–100 Å in diameter, which are similar to those seen in the native Na⁺,K⁺-ATPase fraction. Digestion of the reconstituted proteins with neuraminidase indicated that the glycoprotein moiety of the Na⁺,K⁺-ATPase was asymmetrically oriented in the reconstituted vesicles, with greater than 85% of the total sialic acid directed toward the outside of the vesicles. In contrast, in the native Na⁺,K⁺-ATPase fraction, the glycoprotein was symmetrically distributed. Purified glycoprotein was also asymmetrically incorporated into phospholipid vesicles using Triton X-100 and without detergents as described by R. I. MacDonald and R. L. MacDonald (1975, J. Biol. Chem.250, 9206–9214). The glycoprotein-containing vesicles were 500–1000 Å in diameter, unilamellar, and, in contrast to the vesicles containing the Na⁺,K⁺-ATPase, did not contain the 90- to 100-Å intramembranous particles. These results indicate that the intramembranous particles observed in the native Na⁺,K⁺-ATPase and in the reconstituted Na⁺,K⁺-ATPase are not due to the glycoprotein alone, but represent either the catalytic subunit, or the catalytic plus the glycoprotein subunit.     

Effect of Alkali Metal Cations on Slow Inactivation of Cardiac Na+ Channels

Human heart Na⁺ channels were expressed transiently in both mammalian cells and Xenopus oocytes, and Na⁺ currents measured using 150 mM intracellular Na⁺. The kinetics of decaying outward Na⁺ current in response to 1-s depolarizations in the F1485Q mutant depends on the predominant cation in the extracellular solution, suggesting an effect on slow inactivation. The decay rate is lower for the alkali metal cations Li⁺, Na⁺, K⁺, Rb⁺, and Cs⁺ than for the organic cations Tris, tetramethylammonium, N-methylglucamine, and choline. In whole cell recordings, raising [Na⁺]_o from 10 to 150 mM increases the rate of recovery from slow inactivation at −140 mV, decreases the rate of slow inactivation at relatively depolarized voltages, and shifts steady-state slow inactivation in a depolarized direction. Single channel recordings of F1485Q show a decrease in the number of blank (i.e., null) records when [Na⁺]_o is increased. Significant clustering of blank records when depolarizing at a frequency of 0.5 Hz suggests that periods of inactivity represent the sojourn of a channel in a slow-inactivated state. Examination of the single channel kinetics at +60 mV during 90-ms depolarizations shows that neither open time, closed time, nor first latency is significantly affected by [Na⁺]_o. However raising [Na⁺]_o decreases the duration of the last closed interval terminated by the end of the depolarization, leading to an increased number of openings at the depolarized voltage. Analysis of single channel data indicates that at a depolarized voltage a single rate constant for entry into a slow-inactivated state is reduced in high [Na⁺]_o, suggesting that the binding of an alkali metal cation, perhaps in the ion-conducting pore, inhibits the closing of the slow inactivation gate.     

Of cilia,titin, and neurosteroids

Missense mutations at arginine residues in the S4 voltage-sensor domains of Na_V1.4 are an established cause of hypokalemic periodic paralysis, an inherited disorder of skeletal muscle involving recurrent episodes of weakness in conjunction with low serum K⁺. Expression studies in oocytes have revealed anomalous, hyperpolarization-activated gating pore currents in mutant channels. This aberrant gating pore conductance creates a small inward current at the resting potential that is thought to contribute to susceptibility to depolarization in low K⁺ during attacks of weakness. A critical component of this hypothesis is the magnitude of the gating pore conductance relative to other conductances that are active at the resting potential in mammalian muscle: large enough to favor episodes of paradoxical depolarization in low K⁺, yet not so large as to permanently depolarize the fiber. To improve the estimate of the specific conductance for the gating pore in affected muscle, we sequentially measured Na⁺ current through the channel pore, gating pore current, and gating charge displacement in oocytes expressing R669H, R672G, or wild-type Na_V1.4 channels. The relative conductance of the gating pore to that of the pore domain pathway for Na⁺ was 0.03%, which implies a specific conductance in muscle from heterozygous patients of ∼10 µS/cm² or 1% of the total resting conductance.Unexpectedly, our data also revealed a substantial decoupling between gating charge displacement and peak Na⁺ current for both R669H and R672G mutant channels. This decoupling predicts a reduced Na⁺ current density in affected muscle, consistent with the observations that the maximal dV/dt and peak amplitude of the action potential are reduced in fibers from patients with R672G and in a knock-in mouse model of R669H. The defective coupling between gating charge displacement and channel activation identifies a previously unappreciated mechanism that contributes to the reduced excitability of affected fibers seen with these mutations and possibly with other R/X mutations of S4 of Na_V, Ca_V, and K_V channels associated with human disease.     

Equilibrium and kinetics of thermal unfolding of yeast 5.8S ribosomal RNA in aqueous salt solutions

Equilibrium and kinetics of thermal melting of yeast 5.8S ribosomal RNA in aqueous NaCl were investigated by differential thermal melting and temperature jump methods. Two peaks were observed in each of the melting curves at 1 mM-1 M Na⁺ and linearity between each melting temperature T_m and log[Na⁺] was found at [Na⁺> 10 mM. From the difference spectrum ratio, $\text{d}\text{A}{}_{280}\text{d}\text{A}{}_{260}$, the G-C content in the local structures was calculated to be 91 and 56%. The temperature jump to 70–85°C in aqueous 30 mM Na⁺ of the RNA solution induced first-order kinetics, from which the kinetically determined melting curve was calculated. The curve could be approximately described in a Gaussian form with a T_m which agrees well with the high T_m in the static melting curve at 30 mM Na⁺. The kinetic properties of the reaction indicated a double helix-coil transition. However, the temperature jump to 20–60°C did not induce monophasic kinetics. The kinetic amplitude of the slow component showed a T_m which corresponded to the low T_m in the static melting curve at 30 mM Na⁺. The slow relaxation had the characteristics of a double helix-to-coil transition. However, contributions from very fast processes including single strand unstacking, were most noticeable in the low temperature melting region of the static curve. The thermodynamic parameters of both transitions from double helix to coil were analysed in detail. Both activation energies for helix formation were negative, and the nucleation is thought to follow a process similar to that in oligonucleotides. Values of T_m and enthalpy change of both helix-coil transitions indicated the cloverleaf model as the most plausible one for some limited regions of yeast 5.8S RNA among the previously proposed models: burp gun, cloverleaf and Rubin's models.     

Improved purification and partial characterization of (Na+, K+)-ATPase from cardiac muscle

A method is described for purification of (N⁺, K⁺)-ATPase which yields approximately 60 mg of enzyme from 800 g of cardiac muscle with specific activities ranging from 340 to 400 μmol inorganic phosphate/mg protein per h (units/mg). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated the presence of a major 94 000 dalton polypeptide and four or five lesser components, one of which was a glycoprotein with an apparent molecular weight of 58 000. The enzyme preparation bound 600–700 pmol of [³H]ouabain/mg protein when incubated in the presence of either Mg²⁺ plus P_i or Mg²⁺ plus ATP plus Na⁺, and incorporated more than 600 pmol ³²P/mg protein when incubated with γ-³²P-labeled ATP in the presence of Mg²⁺ and Na⁺. The preparation is approximately 35% pure.     

Metabolic depression and sodium-potassium ATPase in the aestivating frog, Neobatrachus kunapalari

In aestivation the metabolic rate of the Australian desert frog Neobatrachus kunapalari was 50–67% lower than in the non-aestivating state. The rate of O₂ consumption of isolated muscle, skin and brain was measured in both metabolic states. The average rate of O₂ consumption of muscle was 30% lower and brain 50% lower in aestivating frogs, while the rate of O₂ consumption of skin was the same. The reduction in muscle could account for a large proportion of whole animal metabolic depression. To look for evidence of a reduction in energy demand in the tissues we measured the ouabain-sensitive fraction of tissue rate of O₂ consumption, which is considered to be the proportion of metabolism used for transmembrane Na⁺/K⁺ pumping. Ouabain inhibited the in vitro rate of O₂ consumption of skin by a average of 20% and of brain by an average of 30%. However, in muscle, ouabain stimulated in vitro O₂ consumption. Despite the 50% reduction in the in vitro rate of O₂ consumption of brain during aestivation, neither the ouabain-sensitive nor ouabain-insensitive fractions were found be statistically different, possibly because of the large individual variation in the degree of ouabain inhibition. A reduction in the level of ion pumping during aestivation was therefore not demonstrated in any tissue. Measurement of the level of the enzyme Na⁺K⁺-ATPase in skeletal muscle, ventricle, kidney and brain showed that there was no change in the amount of this enzyme in the aestivating frogs. Measurement of the levels of adenylates in muscle and liver showed that the adenylate energy charge was maintained in aestivation, but that there was a reduction in ATP in liver and a reduction in the level of total adenylates in both tissues, which could be an adaptation of the tissues to a lower energy turnover. Accepted: 22 July 1996     

Sodium, Potassium, and Chloride Fluxes in Intercostal Muscle from Normal Goats and Goats with Hereditary Myotonia

In isolated bundles of external intercostal muscle from normal goats and goats with hereditary myotonia the following were determined: concentrations and unidirectional fluxes of Na⁺, K⁺, and Cl^-, extracellular volume, water content, fiber geometry, and core-conductor constants. No significant difference between the two groups of preparations was found with respect to distribution of fiber size, intracellular concentrations of Na⁺ or Cl^-, fiber water, resting membrane potential, or overshoot of action potential. The intracellular Cl^- concentration in both groups of preparations was 4 to 7 times that expected if Cl^- were distributed passively between intracellular and extracellular water. The membrane permeability to K (P_K) calculated from efflux data was (a) at 38°C, 0.365 x 10^-6 cm sec^-1 for normal and 0.492 x 10^-6 for myotonic muscle, and (b) at 25°C, 0.219 x 10^-6 for normal and 0.199 x 10^-6 for myotonic muscle. From Cl^- washout curves of normal muscle usually only three exponential functions could be extracted, but in every experiment with myotonic muscle there was an additional, intermediate component. From these data PP_cl could be calculated; it was 0.413 x 10^-6 cm sec^-1 for myotonic fibers and was 0.815 x 10^-6 cm sec^-1 for normal fibers. The resting membrane resistance of myotonic fibers was 4 to 6 times greater than that of normal fibers.